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202 lines
5.1 KiB
202 lines
5.1 KiB
//
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// REGMEM.C
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//
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// Copyright (C) Microsoft Corporation, 1995
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//
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// Upper-level memory management functions that discards unlocked memory blocks
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// as required to fulfill allocation requests.
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//
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// For the ring zero version of this code, only large requests will call these
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// functions. For most registry files, these requests will already be an
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// integral number of pages, so it's best just to do page allocations. Small
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// allocations, such as key handles, will use the heap services and not go
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// through this code.
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//
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// For all other models of this code, all memory requests will go through this
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// code and memory is allocated from the heap.
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//
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#include "pch.h"
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DECLARE_DEBUG_COUNT(g_RgMemoryBlockCount);
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// For the ring zero version, only large allocations that should be page
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// aligned will pass through these functions.
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#ifdef VXD
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// Converts number of bytes to number of whole pages.
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#define ConvertToMemoryUnits(cb) \
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((((cb) + (PAGESIZE - 1)) & ~(PAGESIZE - 1)) >> PAGESHIFT)
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// Generates smaller code if we don't just make this a macro...
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LPVOID
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INTERNAL
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RgAllocMemoryUnits(
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UINT nPages
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)
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{
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return AllocPages(nPages);
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}
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// Generates smaller code if we don't just make this a macro...
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LPVOID
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INTERNAL
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RgReAllocMemoryUnits(
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LPVOID lpMemory,
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UINT nPages
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)
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{
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return ReAllocPages(lpMemory, nPages);
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}
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#define RgFreeMemoryUnits FreePages
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// For non-ring zero version of the registry code, all allocations will funnel
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// through these functions. All allocations are off the heap.
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#else
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#define ConvertToMemoryUnits(cb) (cb)
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#define RgAllocMemoryUnits AllocBytes
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#define RgReAllocMemoryUnits ReAllocBytes
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#define RgFreeMemoryUnits FreeBytes
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#endif
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//
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// RgAllocMemory
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//
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LPVOID
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INTERNAL
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RgAllocMemory(
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UINT cbBytes
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)
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{
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UINT MemoryUnits;
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LPVOID lpMemory;
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ASSERT(cbBytes > 0);
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MemoryUnits = ConvertToMemoryUnits(cbBytes);
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// Can we allocate from available memory?
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if (!IsNullPtr((lpMemory = RgAllocMemoryUnits(MemoryUnits)))) {
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INCREMENT_DEBUG_COUNT(g_RgMemoryBlockCount);
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return lpMemory;
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}
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RgEnumFileInfos(RgSweepFileInfo);
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// Can we allocate after sweeping all old memory blocks?
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if (!IsNullPtr((lpMemory = RgAllocMemoryUnits(MemoryUnits)))) {
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INCREMENT_DEBUG_COUNT(g_RgMemoryBlockCount);
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return lpMemory;
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}
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// The first sweep will have cleared all the access bits of every memory
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// block. This sweep will effectively discard all unlocked blocks.
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RgEnumFileInfos(RgSweepFileInfo);
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// Can we allocate after sweeping all unlocked and clean memory blocks?
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if (!IsNullPtr((lpMemory = RgAllocMemoryUnits(MemoryUnits)))) {
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INCREMENT_DEBUG_COUNT(g_RgMemoryBlockCount);
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return lpMemory;
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}
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// Flush out every dirty memory block and sweep again.
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RgEnumFileInfos(RgFlushFileInfo);
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RgEnumFileInfos(RgSweepFileInfo);
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// Can we allocate after sweeping all unlocked memory blocks?
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if (!IsNullPtr((lpMemory = RgAllocMemoryUnits(MemoryUnits)))) {
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INCREMENT_DEBUG_COUNT(g_RgMemoryBlockCount);
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return lpMemory;
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}
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DEBUG_OUT(("RgAllocMemory failure\n"));
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// Return lpMemory, which must be NULL if we're here, generates smaller
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// code.
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return lpMemory; // Must be NULL if we're here
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}
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//
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// RgReAllocMemory
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//
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LPVOID
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INTERNAL
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RgReAllocMemory(
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LPVOID lpOldMemory,
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UINT cbBytes
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)
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{
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UINT MemoryUnits;
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LPVOID lpMemory;
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ASSERT(!IsNullPtr(lpOldMemory));
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ASSERT(cbBytes > 0);
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MemoryUnits = ConvertToMemoryUnits(cbBytes);
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// Can we allocate from available memory?
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if (!IsNullPtr((lpMemory = RgReAllocMemoryUnits(lpOldMemory, MemoryUnits))))
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return lpMemory;
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RgEnumFileInfos(RgSweepFileInfo);
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// Can we allocate after sweeping all old memory blocks?
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if (!IsNullPtr((lpMemory = RgReAllocMemoryUnits(lpOldMemory, MemoryUnits))))
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return lpMemory;
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// The first sweep will have cleared all the access bits of every memory
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// block. This sweep will effectively discard all unlocked blocks.
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RgEnumFileInfos(RgSweepFileInfo);
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// Can we allocate after sweeping all unlocked and clean memory blocks?
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if (!IsNullPtr((lpMemory = RgReAllocMemoryUnits(lpOldMemory, MemoryUnits))))
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return lpMemory;
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// Flush out every dirty memory block and sweep again.
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RgEnumFileInfos(RgFlushFileInfo);
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RgEnumFileInfos(RgSweepFileInfo);
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// Can we allocate after sweeping all unlocked memory blocks?
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if (!IsNullPtr((lpMemory = RgReAllocMemoryUnits(lpOldMemory, MemoryUnits))))
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return lpMemory;
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DEBUG_OUT(("RgReAllocMemory failure\n"));
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// Return lpMemory, which must be NULL if we're here, generates smaller
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// code.
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return lpMemory;
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}
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#ifdef DEBUG
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//
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// RgFreeMemory
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//
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VOID
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INTERNAL
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RgFreeMemory(
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LPVOID lpMemory
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)
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{
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ASSERT(!IsNullPtr(lpMemory));
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DECREMENT_DEBUG_COUNT(g_RgMemoryBlockCount);
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#ifdef ZEROONFREE
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ZeroMemory(lpMemory, MemorySize(lpMemory));
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#endif
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RgFreeMemoryUnits(lpMemory);
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}
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#endif
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